DE1290722B - Use of a nickel alloy as a material for nozzles to produce glass threads in the melt flow - Google Patents

Description

1 2

The invention relates to a material for nozzles molten glass in contact appa-

for the production of glass threads in the melt flow, the rateteile.

is particularly suitable for this purpose. The term the inventor has established how this is also "Nozzles" should be understood broadly. A nozzle in the remarks below shows that the For the purposes of the invention includes any organ that has the opening 5 of the above alloy at the intended twisting has, through the molten glass in the form of an extremely favorable combination of manure thin streams emerge, which then become threads or less abrasion and great creep resistance be pulled out. The openings mentioned are possible.

are generally of small diameter, the following is an example of an embodiment molten glass flowing through it has io alloy to be used according to the invention with the following

a high temperature, and the »nozzles« are listed according to their composition: even exposed to high temperature.

In particular, the invention also relates to a nickel 51.95%

Material for use in hollow rotating bodies that combine chromium 28 80% with a large number of outflow openings 15

have seen jacket, through which the molten niobium + tantalum 5%

zene glass is ejected in the form of threads, tungsten 2.47%

which are then drawn out into fibers. _rr ,, ",«., - ",

The invention is based on the object of a carbon 0.47%

to use such an alloy as a material that 20 boron 0.14%

this is achieved through an advantageous combination of silicon 0 20%

low abrasion and high creep resistance '

under load at high temperature while flowing Manganese 0.87%

of molten glass, especially iron remnants

if this passes through the narrow "nozzle" openings 25

flows. The alloys of the invention have one

It is already the use of nickel alloy- low expansion coefficient, which is also

genes with a high chromium content for the above changes relatively little with temperature. So

hollow rotating body for ejecting an alloy according to the above example Molten glass in the form of threads known to have a coefficient of expansion that differs from

(see U.S. Patent 3,010,201). The alloy 13.00-10- «at normal temperature to 17.25 · 10" ⁶

tion according to this USA. patent has changed at 1100 ° C.

the operating conditions in question here. The alloys according to the invention also have

only a service life of approximately 120 to 150 hours, particularly important properties with regard to a the, exceptionally, of 200 hours. Such a creep and with regard to a resilience

Relatively short service life, however, means a speed against corrosion.

Considerable disadvantage when you consider that the alloy according to the above type of rotating body was relatively expensive, guide example subjected to creep tests and when you also consider that each from a load of 2 kg / mm ² with a temperature change 40 _V on 1050 ^: C. The alloy went only after a very serious interruption in operation. Also the long time to break, namely according to approximately French patent specification 1274 925 reveals the 640 hours. In contrast, the known use of a nickel-chromium alloy for the usual alloys under the same conditions-nozzles for the mentioned rotating bodies for ejecting already break after a time, which is the size of molten glass in the form of threads. 45 of the order of 200 hours. The alloy according to this patent shows the curves of FIG. 1 of the drawing show the course of creep at 1050 ° C. below 2 kg / mm ² against corrosion, as it is caused by the flow of the load on a known alloy (curve A) of glass through narrow openings through particularly increased resistance. the following composition in the rest almost This alloy does not have the advantageous combination 50 is identical with the alloy according to Example 1 tion of low abrasion and high creep resistance of the _n} USA. Patent 3 010201: speed coming in here in question Operating conditions, if they also, as below Chromium 26.6%

it can be seen has a similar composition ^. ,. "

like the alloy 55 to be used according to the invention

tion. Carbon 0.43%

The object on which the invention is based is achieved by using an alloy of 25 bis tungsten 5 6%

33%, preferably 28 to 32% chromium, 45 to 53%, silicon 1%

preferably 48 to 53% nickel, 3.5 to 6%, preferably 60 manganese 1.06%

preferably 3.5 to 5% niobium, of which up to 0.5%. _R.

can be replaced by tantalum, 1 to 5%, preferred iron remainder

wise 3 to 5% tungsten, 0.3 to 0.6%, preferably

0.4 to 0.5% carbon, 0 to 2%, preferably and an alloy to be used according to the invention - 0.5 to 1.5% manganese, 0 to 0.5% silicon, 0.1 to 65% (curve B ), which had the composition of 0.4% boron, the remainder iron including the usual above-mentioned exemplary embodiment. The contaminants as a material for nozzles for heart cushions indicate the duration in hours, and represent glass threads in the melt flow and others with, although on a logarithmic scale, and the ordinates

3 4

indicate the (permanent) elongations in percent, alloy composition listed below

on a linear scale. tongues:

The invention generally includes use. . , " _T " · , _Tr ^

the above-mentioned alloys as a material in the ¹ J ¹¹¹ application of a normal alloy (curve C)

Production of metallic apparatus parts, which for ^{the fol} 5 g ^composition:

contact with molten glass determines chromium ^ 4 ° /

(e.g. containers, electrodes or the like). It includes ~

especially the formation of metallic parts, nickel 19%

the openings generally small diameter silicon 2%

wear through which molten glass high tem- ο

temperature flows and the "even at high temperatures carbon 0.30%

be brought. Manganese 0.30%

The invention particularly includes the application of iron remainder
tion of these alloys as a material for rotating

Hollow bodies, such as those used for glass fiber production using a known alloy, such as are used, and which have a circumferential wall defined above on the occasion of the curve that relates to creeping with a large number of openings ( Curve D);
can be seen through which the molten glass is thrown out using a shape to be formed according to the invention of threads, which then turning alloy of the type are drawn out into fibers accordingly. Such hollow bodies 20 of _{the embodiment described above} work under particularly difficult conditions (curve E)
due to the very high temperatures to which they are exposed

are brought, are given, in particular because the times are plotted on the abscissas,

the high temperature of the gases which are the external during which the test pieces of effect

Touch the surface of the peripheral wall. 25 subjected to the stream of molten glass

In Fig. 2 of the drawing is a vertical section in FIG. The ordinates show the weight losses

Axial direction of such a rotating body in percent.

shown per 1, the circumferential wall 2 of The tests were carried out with a glass of medium

a large number of openings 3 is pierced. Viscosity of llOOPoise at a temperature of

The molten glass 4 is made into a distributor 5 3 ° 1030 ° C. This glass had the following

guided, which basket shape has and its vertical composition:
Wall is also provided with openings 6. Of the

Basket 5 is rotated by the rotating body 1 in Ro-SiO ₂ 61.25%

tation shifted, and the molten glass is §q 0 31%

through the openings 6 to the inside of the circumference 35 ³

flapping wall 2 so that the glass is Fe ₂ O ₃ 0.40%

this wall is distributed essentially uniformly ALO., 4.00%

is. Under the effect of centrifugal force the cn 8 ^ n 0 /

molten glass through the openings 3 in the form ^a '~ "

flung out by threads, which then turn into fine 40 MgO 4.10%

Fibers are drawn out. It is also a ^ a q 22 55 < > / ,,

Combustion chamber 7 shown, which is generally ²

ncn is ring-shaped and a rotating body k ₂ O 0.4J%

has coaxially surrounding relaxation opening 8, B ₀ O., 5.20%

from the combustion gases at high speed 45 ~ " ,

and high temperature, which are marked with '°

come into contact with the material flows, which consist of F 2.50%

the openings 3 have been ejected, and

cause them to pull out into very fine fibers. It should be noted that the alloys according to FIG

It can be seen that such a rotating body has a certain hardness. This hardship

and in particular its circumferential wall, however, is very not such that it makes processing

is exposed to high temperatures with respect to these alloys under conditions such as they are for

the materials used are a large resistance heat-resistant steels of the usual type,

make it necessary to be able to crawl. That prevents. It should be noted that with the

In addition, it must be taken into account that the glass, which is made of alloys, distributors or baskets

also has a high temperature, significant places that cannot be welded and which

has a corrosive effect when it passes through using the centrifugal method,

through the openings of both the rotating body. The alloy to be used according to the invention

as well as the distributor basket. contains more chromium and less nickel than that

The alloys according to the invention allow an alloy according to the French patent specification

significant extension of the service life of this 1274 925. Furthermore, the invention includes

Facilities, namely the hollow body and the alloy used on the components according to

Distribution organs, niobium, going beyond the French patent specification because of their great resistance

ability against corrosion by the glass and the respectively tantalum, tungsten, boron and iron, while the

Combustion gases. 65 components cobalt, aluminum and titanium of the

The curves of FIG. 3 show the relative yawing according to the French patent specification in FIG

weight loss in percent of two centrifugal bodies according to the invention to be used alloy not

same shape and dimensions, but with the included.

A comparison of the properties of the alloy according to the French patent with those of The alloy to be used according to the invention results in the following: First, the curve from FIG French patent with the Fig. 3. It can be seen that the removal by the molten glass in the alloy according to the French patent is even less than the removal in the case of the alloy to be used according to the invention, that is to say according to FIG Curve £ in Fig. 3. It should now be expressly pointed out that to be used according to the invention Alloy is not aimed at the lowest possible removal, but on an advantageous as possible Combination of low abrasion and high creep resistance under load at high temperatures. In this regard, reference is made to the curves in FIG. 1 already discussed above Experiments carried out by the inventor have been found that the alloy to be used according to the invention has particularly good properties in terms of resistance to this creep, the are also better than those of the alloy according to the French patent.

Overall, the tests have shown that the alloy to be used according to the invention is the alloy according to the French patent is superior in terms of combining a small Abrasion by the glass melt flow with the resistance to creep under load high temperature.

Claims (3)

Patent claims: 1. Use of an alloy of 25 to 33%, preferably 28 to 32% chromium, 45 to 53%, preferably 48 to 53% nickel, 3.5 to 6%, preferably 3.5 to 5% niobium, of which up to can be replaced by tantalum to 0.5%, 1 to 5%, preferably 3 to 5% tungsten, 0.3 to 0.6%, preferably 0.4 to 0.5% carbon, 0 to 2%, preferably 0.5 to 1.5% manganese, 0 to 0.5% silicon, 0.1 to 0.4% boron, the remainder iron including the usual impurities as a material for nozzles for the production of glass filament in the melt flow and others with melted Apparatus parts in contact with glass. 2. Use of an alloy according to claim 1 from 51.95% nickel,
28.80% chromium, 5% niobium + tantalum, 2.47% tungsten, 0.47% carbon, 0.14% boron, 0.20% silicon, 0.87% manganese, Remainder iron for the purpose specified in claim 1. 3. Use of an alloy according to claim 1 or 2 for the purpose according to claim 1, wherein hollow rotating body with a jacket which is provided with a plurality of openings, through which the molten glass is ejected in the form of threads, which then close Fibers are drawn out, entirely or at least at the spinning orifices, from the chromium-nickel alloy exist. 1 sheet of drawings